Nonsense-mediated mRNA decay is a highly conserved mRNA decay pathway that serves an RNA surveillance mechanism by ridding cells of premature termination codon-containing mRNAs encoding potentially harmful truncated proteins. It also regulates the accumulation of approximately five percent of the normal cellular mRNAs in yeast ( S. cerevisiae), fruit flies (Drosphila melanogaster) and humans. Further it is essential for mammalian viability. Thus nonsense-mediated mRNA decay serves an important cellular function in normal regulation of gene expression. Our long-term goal is to understand the molecular mechanisms responsible for recognition and targeting of wild-type mRNAs for degradation by this pathway and the contributions of this pathway to gene regulation.

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Nonsense-mediated mRNA decay is a highly conserved mRNA decay pathway that serves an RNA surveillance mechanism by ridding cells of premature termination codon-containing mRNAs encoding potentially harmful truncated proteins. It also regulates the accumulation of approximately five percent of the normal cellular mRNAs in yeast (''S. cerevisiae''), fruit flies (''Drosphila melanogaster'') and humans. Further it is essential for mammalian viability. Thus nonsense-mediated mRNA decay serves a second important cellular function in normal regulation of gene expression. Our long-term goal is to understand the molecular mechanisms responsible for recognition and targeting of wild-type mRNAs for degradation by this pathway and the contributions of this pathway to gene regulation.

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We have shown that the normal cellular mRNA, PPR1 mRNA, is targeted for nonsense-mediated mRNA decay by a unique mechanism that depends on 1) the same cellular factors that are involved in the decay of nonsense mRNAs and 2) a specific region of the PPR1 mRNA. PPR1 encodes a transcription activator and increasing PPR1 mRNA levels by inhibiting nonsense-mediated mRNA decay in turn results in an increase in the expression of Ppr1-activated genes. From the lessons learned studying PPR1 mRNA decay, we have developed a novel bioinformatics approach to identify other mRNAs regulated by the yeast nonsense-mediated mRNA decay pathway.

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We have shown that the normal cellular mRNA, ''PPR1'' mRNA, is targeted for nonsense-mediated mRNA decay by a unique mechanism that depends on 1) the same cellular factors that are involved in the decay of nonsense mRNAs and 2) a specific region of the PPR1 mRNA. ''PPR1'' encodes a transcription activator and increasing ''PPR1'' mRNA levels by inhibiting nonsense-mediated mRNA decay in turn results in an increase in the expression of Ppr1-activated genes. From the lessons learned studying ''PPR1'' mRNA decay, we have developed a novel bioinformatics approach to identify other mRNAs regulated by the yeast nonsense-mediated mRNA decay pathway.

Currently we are examining the role of nonsense-mediated mRNA decay in regulation of normal cellular mRNA decay. We are: (1) Identifying additional normal cellular mRNAs that are degraded by the nonsense-mediated mRNA and investigating the mechanisms targeting these mRNAs for decay; (2) Examining the conservation of normal cellular mRNA decay by nonsense-mediated mRNA decay. This work is funded by a grant from the National Science Foundation (MCB-0444333).

Currently we are examining the role of nonsense-mediated mRNA decay in regulation of normal cellular mRNA decay. We are: (1) Identifying additional normal cellular mRNAs that are degraded by the nonsense-mediated mRNA and investigating the mechanisms targeting these mRNAs for decay; (2) Examining the conservation of normal cellular mRNA decay by nonsense-mediated mRNA decay. This work is funded by a grant from the National Science Foundation (MCB-0444333).

Candida albicans is an important opportunistic human pathogen. It normally resides in the gastrointestinal and genitourinary tract and to a lesser extent on the skin of most humans. However, given the opportunity, it can cause candidemia where it invades host tissues, progresses to growth of fungal masses in the kidney, heart or brain, and ultimately can cause death. Candida morphogenesis is important for development of candidemia. Patients with compromised immune systems are at high risk for candidemia. Many patients with candidemia die by the time laboratory diagnosis is made. Further, there is still substantial mortality of patients who receive antifungal treatment. Consequently there is a need for development of molecular probes that facilitate earlier clinical diagnosis and new classes of antifungal drugs.

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''Candida albicans'' is an important opportunistic human pathogen. It normally resides in the gastrointestinal and genitourinary tract and to a lesser extent on the skin of most humans. However, given the opportunity, it can cause candidemia where it invades host tissues, progresses to growth of fungal masses in the kidney, heart or brain, and ultimately can cause death. ''Candida'' morphogenesis is important for development of candidemia. Patients with compromised immune systems are at high risk for candidemia. Many patients with candidemia die by the time laboratory diagnosis is made. Further, there is still substantial mortality of patients who receive antifungal treatment. Consequently there is a need for development of molecular probes that facilitate earlier clinical diagnosis and new classes of antifungal drugs.

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Candida can grow vegetatively as yeast, hyphae or pseudohyphae. It posesses the ability to interconvert between these different morphological forms in response to its environment. There is a strong correlation between morphological interconversion and pathogenicity. The morphological transition is regulated, in part, by farnesol. Farnesol is synthesized by Candida and it blocks the conversion of yeast to hyphae or pseudohyphae in response to most, if not all, of the chemical and environmental morphogenesis inducers. Farnesol also acts as a virulence factor for systematic Candida infections in a mouse model, and the response to farnesol is unique to Candida because it does not block the morphological transition in the other dimorphic fungal species we have tested. We are part of a multidisciplinary team studying the role of farnesol. We are determining how Candida interprets signaling by farnesol at the level of gene regulation and expression, and then executes this regulation through changes in cell structure, dynamics and function.

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''Candida'' can grow vegetatively as yeast, hyphae or pseudohyphae. It posesses the ability to interconvert between these different morphological forms in response to its environment. There is a strong correlation between morphological interconversion and pathogenicity. The morphological transition is regulated, in part, by farnesol. Farnesol is synthesized by Candida and it blocks the conversion of yeast to hyphae or pseudohyphae in response to most, if not all, of the chemical and environmental morphogenesis inducers. Farnesol also acts as a virulence factor for systematic ''Candida'' infections in a mouse model, and the response to farnesol is unique to ''Candida'' because it does not block the morphological transition in the other dimorphic fungal species we have tested. We are part of a multidisciplinary team studying the role of farnesol. We are determining how Candida interprets signaling by farnesol at the level of gene regulation and expression, and then executes this regulation through changes in cell structure, dynamics and function.

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An understanding of how Candida responds to farnesol is important because it will reveal a whole new layer of fungal morphogenesis control that, in turn, should provide a series of new target sites for the design of antifungal drugs. Further, the specificity of farnesol for control of the Candida morphological transition suggests that the genes for farnesol response may be unique to Candida and thus these genes are candidates for molecular probes for rapid clinical diagnosis.

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An understanding of how ''Candida'' responds to farnesol is important because it will reveal a whole new layer of fungal morphogenesis control that, in turn, should provide a series of new target sites for the design of antifungal drugs. Further, the specificity of farnesol for control of the ''Candida'' morphological transition suggests that the genes for farnesol response may be unique to ''Candida'' and thus these genes are candidates for molecular probes for rapid clinical diagnosis.

Nonsense-mediated mRNA decay is a highly conserved mRNA decay pathway that serves an RNA surveillance mechanism by ridding cells of premature termination codon-containing mRNAs encoding potentially harmful truncated proteins. It also regulates the accumulation of approximately five percent of the normal cellular mRNAs in yeast (S. cerevisiae), fruit flies (Drosphila melanogaster) and humans. Further it is essential for mammalian viability. Thus nonsense-mediated mRNA decay serves a second important cellular function in normal regulation of gene expression. Our long-term goal is to understand the molecular mechanisms responsible for recognition and targeting of wild-type mRNAs for degradation by this pathway and the contributions of this pathway to gene regulation.

We have shown that the normal cellular mRNA, PPR1 mRNA, is targeted for nonsense-mediated mRNA decay by a unique mechanism that depends on 1) the same cellular factors that are involved in the decay of nonsense mRNAs and 2) a specific region of the PPR1 mRNA. PPR1 encodes a transcription activator and increasing PPR1 mRNA levels by inhibiting nonsense-mediated mRNA decay in turn results in an increase in the expression of Ppr1-activated genes. From the lessons learned studying PPR1 mRNA decay, we have developed a novel bioinformatics approach to identify other mRNAs regulated by the yeast nonsense-mediated mRNA decay pathway.
Currently we are examining the role of nonsense-mediated mRNA decay in regulation of normal cellular mRNA decay. We are: (1) Identifying additional normal cellular mRNAs that are degraded by the nonsense-mediated mRNA and investigating the mechanisms targeting these mRNAs for decay; (2) Examining the conservation of normal cellular mRNA decay by nonsense-mediated mRNA decay. This work is funded by a grant from the National Science Foundation (MCB-0444333).

Photographs of double-labelled yeast cells showing Upf1p (left), DNA stained with DAPI (center), and yeast cells (right). This approach was used to show that Upf1p is primarily found in the cytoplasm.

Regulation of Candida albicans morphogenesis by quorum sensing

Candida albicans is an important opportunistic human pathogen. It normally resides in the gastrointestinal and genitourinary tract and to a lesser extent on the skin of most humans. However, given the opportunity, it can cause candidemia where it invades host tissues, progresses to growth of fungal masses in the kidney, heart or brain, and ultimately can cause death. Candida morphogenesis is important for development of candidemia. Patients with compromised immune systems are at high risk for candidemia. Many patients with candidemia die by the time laboratory diagnosis is made. Further, there is still substantial mortality of patients who receive antifungal treatment. Consequently there is a need for development of molecular probes that facilitate earlier clinical diagnosis and new classes of antifungal drugs.

Candida can grow vegetatively as yeast, hyphae or pseudohyphae. It posesses the ability to interconvert between these different morphological forms in response to its environment. There is a strong correlation between morphological interconversion and pathogenicity. The morphological transition is regulated, in part, by farnesol. Farnesol is synthesized by Candida and it blocks the conversion of yeast to hyphae or pseudohyphae in response to most, if not all, of the chemical and environmental morphogenesis inducers. Farnesol also acts as a virulence factor for systematic Candida infections in a mouse model, and the response to farnesol is unique to Candida because it does not block the morphological transition in the other dimorphic fungal species we have tested. We are part of a multidisciplinary team studying the role of farnesol. We are determining how Candida interprets signaling by farnesol at the level of gene regulation and expression, and then executes this regulation through changes in cell structure, dynamics and function.

An understanding of how Candida responds to farnesol is important because it will reveal a whole new layer of fungal morphogenesis control that, in turn, should provide a series of new target sites for the design of antifungal drugs. Further, the specificity of farnesol for control of the Candida morphological transition suggests that the genes for farnesol response may be unique to Candida and thus these genes are candidates for molecular probes for rapid clinical diagnosis.